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A, ,:,,r"W OOD K CONSERVING
COOK STOVES * A Design Guide
AP A
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Front cover: "The Wood Gatherer," an original woodcut by VITA Volunteer Rosemary Feit Covey. Available in a limited edition of signed prints on Japanese rice paper. $25.00 (US) each plus $2.00 (US) postage and handling. Proceeds from the sale will support VITA's publication efforts.
ISBN 0-86619-000-7
1980 Volunteers in Technical Assistance
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WOOD CONSERVING COOK STOVES
A Design Guide
Funded by Al Dir'iyyah Institute Geneva, Switzerland
Published by Volunteers in Technical Assistance
3706 Rhode Island Avenue Mt. Rainier, Maryland 20822 USA
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WOOD CONSERVING COOK STOVES, A Design Guide, promotes stoves
and cooking methods that are inexpensive, culturally acceptable, and environmentally sound. It is meant especially for
field or extension workers, and is aimed at engineers, end users, and all those interested in wood stove design and use.
Enough information is contained in the manual for the reader to:
. choose an appropriate stove 0 understand how wood burns . know what makes a stove more efficient . construct four stoves
All of this information is provided to support local stove efforts and expand the dialogue among stove builders. Readers are urged to use the bound-in reply form to share their experiences.
A second volume of this book is planned. It will focus on how to introduce stoves through small-scale local programs, taking into account the social and cultural aspects of stove design. It will also include information on testing stoves.
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Contents Acknowledgements ..................... vii
Introduction ........... o.......... ........ ............ 1
1. HOW TO USE THIS BOOK .................................. 7
2. HOW STOVES WORK . . ...... .... .. ...... ........... 9
How wood burns ............................ o.......... 9
How heat is transferred ............................... 12
Conduction Radiation Convection
How heat is contained ... ................... ....... 15
Stove components Traditional stoves Simple metal stoves
3. HOW TO MAKE STOVES EFFICIENT.......................... 29
Conserving heat .. ..... . ... ...... ........... ....... 29
Energy losses in stoves Improving combustion efficiency Using the heat from the gas stream Minimizing heat loss from heating the stove Minimizing heat losses from pots and stove walls
Improving traditional stoves ......................... 33
Combustion chamber engineering The chimney-and-damper approach Improving combustion efficiency
Improving stove building materials ................... 47
Cast iron, steel plate and sheet metal Ceramic Mud and brick
Previous Page Blank
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4. HOW TO BUILD FOUR STOVES .......... .................... 55
Lorena stove ..................... ..... 55
Materials Tools and equipment Construction Use of the stove
*** 000Smokeless chula ... ............. 000 0 0*0*0*0* 71
Materials Construction Use of the stove
Singer stove .... .... a... . . .. .. ... .. . . . . 83
Materials Construction Use of the stove
Sawdust cook stove ............ ....................... 94
Materials Tools and equipment Construction Use of the stove
5. HOW TO USE STOVES EFFICIENTLY .. ..................... 99
Choosing wood ...o........ . . ...... . ........... 99
Using wood .......... . . . .. . . . .. . ....... '102
Dictionary of Terms .......... ....................... . 105
.................. .. *.......Bibliography ..... . .......... * 109
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Acknowledgements
This manual has been made possible by a grant from the al
Dir'iyyah Institute of Arlington, Virginia, and Geneva,
Switzerland.
No manual like this is produced without the work of many
hands. Special thanks go to Kristine Stroad Ament, and to
Stephen Joseph of the Intermediate Technology Development Group
for editing, to William Gensell and Michael Boutette for illus
trating, to Bonnie Duley for layout, and to E. Christopher Cone
for typesetting. Past and present VITA staff researchers,
writers, and editors include Margaret Crouch, Laurel Druben,
Gregory A. James, David Jarmul, Alice Manker, and William
Magrath.
VITA volunteers and others who reviewed the book for technical
accuracy include Nancy Axinn, Dr. Norman Brown, Dr. Gautam
Dutt, David Hughart, Dr. Larry Icerman, and Jeff Wartluft.
Volunteers in Technical Assistance June 1980
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Introduction
The costs of using firewood in traditional ways are growing
every day. Fuelwood is the primary source of energy for house
holds in developing countries (Openshaw, 1974). It is used
mainly for domestic cooking and, to a lesser extent, for heat
ing and industry.
Population pressure in many areas has made the demand for fire
wood consistently exceed the supply. The consumption of wood in
Nepal is seven times greater than the annual forest yield. The
price of firewood in Kathmandu has tripled in three years
(Karki and Coburn, 1977).
The "cost" of gathering firewood in India has been found to be
between 200 and 300 person-days per family per year--a full
time job for one person. It is common in sub-Saharan Africa to
travel by foot or animal-drawn cart more than 50km (30 miles)
for firewood. Firewood can cost as much as one-quarter of the
family's income in areas where it is purchased.
The soil deteriorates and retains less water as timber
resources are depleted. This leads to desertification in some
areas and to severe flooding in others. Most poor people in
Third World countries are 'energy-gatherers' (Reddy, 1976).
They cannot aEford to buy fossil fuels. They have no alterna
tive, such as biomass fuels. Fuel for cooking is a necessity.
Even if such people are aware of a conflict between short- and
long-term interests, they are too poor to postpone their imme
diate needs for such long-term gains as maintaining soil
fertility.
For the cook and the cook's family, the problems do not end
once the firewood is gotten. Smoke from open fires and inef
ficiet.t stoves can create a dirty, unhealthy situation. Eye and
respiratory problems are wide-spread. Burns and scalds-
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especially with children--are numerous. Flying sparks create a
constant fire hazard. Even without these serious dangers, a
smoke-filled, soot-blackened cooking area is neither a pleasant
nor healthy place in which to work.
On a wider scale, the problems caused by deforestation are not
hard to see--when one has the time and opportunity to view them
from a broad perspective. However, wood usage problems remain far more personal for most users. Most families must adjust to increased demand as wood becomes ever harder to find.
It is likely that wood and other biomass fuels will be primary fuels for these people for some time. Such alternatives as solar cookers and methane digesters are more likely to be used in small-scale industrial processing than in homes.
The wood fuel shortage must be attacked on several fronts simultaneously to meet the growing ecological crisis. Resources must be conserved through comprehensive reforestation programs and well-managed village wood-lots (Earl, 1975; Openshaw, 1973).
Many proposed solutions have a long-range focus. Few seek to change current patterns of use. But the only immediate hope is to reduce end usage. Even a 10 or 20 percent reduction in the use of firewood can have significant results. The demand for firewood can be reduced by designing and introducing stoves that are efficient, cheap, and culturally acceptable.
Despite the fact that a number of efforts are underway to develop wood-conserving cook stoves, little effort has been made to draw the results together and look at them in terms of their similarities and differences. Even less has been done to teach principles of stove design. This knowledge is essential for stove building efforts. A review of the state-of-the-art suggests that while different in appearance and construction materials, improved wood cook stoves are all based on the same design principles.
The information available on wood cook stoves is scattered and sometimes too oriented to research. Existing materials may be
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do not aim at getting stove technology into thehard to read or bands of local users.
to be that planners haveThe reason for the lack of data seems
for years assumed that people advanced from wood fires to an
gas range, not to an improved wood-burning cookelectric or
stove. It just was not considered necessary to think very hard
about a better cooking system based on wood usage.
inTwo major world forces today require more work to be done
the wood stove area. One force is provided by the more devel
oped countries as they seek alternatives to a heavy and expen
sive dependency on gas and electricity, particularly on a
the same time, it has become almostpersonal-use level. At
impossible in some less developed countries to find wood. Gas
and electricity are either unavailable or too expensive.
It should be noted clearly that the reason for moving from wood
stoves to cooking systems based on other power sources--in the
occurred over time--was that these otherareas where this has feasible. They were efficient, clean,sources became more
cheap. Today, the state of the worldseemingly abundant, and
suggests that wood-burning systems, at least improved ones, are
a more attractive alternative for some applications than was
interest in many developed countries is inonce thought. The wood stoves for space heating. The emphasis in less
industrialized countries is on improved cooking stoves, the
subject of this manual.
Based on the data collected during a search of worldwide
literature and in consultation with a number of experts, VITA
chose a small number of wood conserving stove technologies to
be highlighted in this manual. The technologies were chosen on
the basis of (1) the way in which the stove incorporates design
principles and shows the adaptation of a basic design to meet
local situations, and (2) its ability to serve as a model for
both technology adaptation and introduction. In other words,
one of the key criteria is that the technology can be taken
successfully from the workshop into the marketplace.
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Perhaps the most basic design comes from India, where much work
with cook stoves was started with the interest of Mohandis Gandhi in programs for rural areas. The major research result in India has been the Hyderabad Engineering Research Laboratory chula, better known today as the HERL chula. Chula (also spelled "chulah") simply means cooking place. The HERL chula was based on traditional Indian fireplaces, and adapted by S.P. Raju, former director of the Laboratory. Many stove designs being promoted throughout the world today are based on the HERL chula.
A description of the HERL chula provides a good overview of improved stoves. The HERL chula is basically a block of clay and sand. A tunnel runs horizontally through it. Holes to fit the cooking vessels are cut through the top of the block. The fire is built at one end of the tunnel beneath the first pot. A chimney of clay or sheet metal is installed at the other end. Hot gases and flames flow within the chula through the tunnel, under the pots, and up the chimney. A damper provides draft control. The number of pots and the size and height of the stove can be adjusted to the user's preferences. Because it forms the basis for so many other stoves, a modification of the HERL, the smokeless chula, is presented in 4. HOW TO BUILD FOUR STOVES.
Complete descriptions of two adaptations of the HERL chula have also been included: the Lorena stove and the Singer stove. While both stoves rely on the same basic design elements--a tunnel carrying hot gases under and around pots held above--the stoves provide models of how the basic chula has been adapted to local cooking preferences and to available building materials.
The Lorena stove is built from a massive sand and clay block, while the Singer stove is assembled from smaller blocks. The description of the Lorena stove begins on page 55. The description of the Singer stove begins on page 83.
In addition to the modified chulas, other stoves have been designed for burning other organic fuels--such as sawdust or rice hulls. (A description of a sawdust cook stove begins on
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page 94.) The practice is not new. Such materials have been
used for some time. In Upper Volta, for example, millet stalks
are burned almost exclusively for six months of the year. Wood
is used the rest of the time. In south Asia, cakes of cattle dung are used as a fuel supplement.
The use and availability of alternative fuels affect the type
of stove that can or should be constructed. Slight changes in
the design of a stove can make it adaptable for burning wood
and alternative fuels. Again, the process depends upon under
standing the design criteria. This manual includes several suggestions for wood-conserving stoves that can be used to burnalternative fuels.
While most improved cooking systems depend upon relatively
large stationary stoves, this guide also includes some suggestions for making relatively small, portable stoves from 20-liter (5-gallon) metal containers. These stoves have definite advantages in areas where the population is mobile or
for city-dwellers who must cook outside for reasons of space and health.
The less portable stoves highlighted in this manual can be
built to any height desired. Cooks in some cultures squat while
cooking their food. In other cultures they stand. A lower stove requires less materials to build, but a stove that is about waist high is very convenient to use and is safer if small children are present. Of course the size and number of pot holes can be varied as well.
Even with technical considerations, the stove designer must carefully examine the range of functions served by a
traditional stove. For example, a stove with a chimney to
provide draft is more efficient than a stove lacking a chimney. However, people in Bangladesh do not regard chimneys as desirable because they need to keep stormwater out during monsoon rains. Smokeless stoves have also proved unacceptable in many plfces because people depend on smoky fires to keep
thatched roofs dry and insect-free. Roofs do not last as long with a smokeless stove. Both of these examples illustrate how
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designers can be misled if they consider only those technical functions of stoves with which they are familiar from their own cultures.
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1. HOW TO USE THIS BOOK
This book explains what fire is, and then discusses the various
ways in which fire is enclosed. The material is based on information from VITA's Documentation Center, and on the
experiences of wood stove experts and dsers. This manual requires no special technical skills.
Each section is carefully designed to provide information to help readers build the stove most useful to their needs. The
chapters are as follows:
2. HOW STOVES WORK explains in a simple way what fire and heat are, and describes basic stoves and their components.
3. HOW TO MAKE STOVES EFFICIENT discusses the ways in which stoves can be made to conserve heat, including design principles, improvements on traditional stoves, and better building materials.
4. HOW TO BUILD FOUR STOVES gives design, construction, use, and maintenance information for the Lorena, smokeless chula,
Singer, and sawdust cook stoves.
5. HOW TO USE STOVES EFFICIENTLY outlines the characteristics of wood as fuel.
A DICTIONARY OF TERMS gives clear definitions for many technical terms used in the book.
A USER'S QUESTIONNAIRE is bound into the back of the book. This
evaluation form is to be filled out and returned to VITA by users of the manual. The information will be used to revise and update future editions.
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2. HOW STOVES WORK
Fire is so important to human health and comfort that for many
years the Greeks and others thought it to be one of the basic
that fire comes from aelements of the universe. We now know
source of heat applied to fuel in the presence of air.
How wood burns
Air is made of gases, mainly oxygen (02) and nitrogen (N2 ). the wood, orHeat sources can be the sun, its rays focused on
the fleme from a match or flint. The fuel in this case is
wood. Wood is made mostly of cellulose, lignin, water (H20), substance; itresin, and other material.s. Wood is an organic
once was a living thing.
the wood gives offWhen heat is applied, the surfare layer of
water, carbon dioxide (C02), and some organic acids (see
Figure 1). The carbon dioxide and the water vapor cover the
surface of the wood and prevent oxygen from coming into contact
with the wood. This results in smoke but no flame.
As the temperature rises, the surface of the wood chars (burns
time, heat is sent inward throughinto charcoal). At the same
to be freed from the inner part ofthe wood. This causes water
tar are freed. They spread over thethe wood. Then gases and
surface of the wuod. The tar reacts with the char to form vola
tile gases. These produce a flame, in the presence of oxygen.
The flame gives out heat.
Each gas requires a certain amount of air and must reach a cer
ignite. The greater the amounttain temperature before it will
of air, the more heat the gases will carry away. But the wood
will not ignite if the pro,)ortion of excess air exceeds a cer
are too few chemical reactionstain limit. In this case, there
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Previous page BAl
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I5VOLATILFrWOOD
Figure 1 0
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to generate the heat necessary to compensate for the loss of
heat from the reaction area. This also occurs when there is not
enough air present.
Once ignited, the gases burn with a luminous flame. The heat
from the wood until only carboncontinues to drive more gases monoxide and hydrogen are given out, The charcoal merely glows
with little or no flame.
An average of 30 percent of the radiation energy (see next sec
tion) is reabsorbed by the wood. This helps maintain the burn
ing process.
The various reactions of the oxygen in the incoming air can be
summarized as follows:
Substances Where the ProductsWhich React Reaction Occurs
fuel surface carbon monoxide,Char + air
......-> carbon dioxide
carbon monoxide,Tar + air flame
......-> carbon dioxide,
and waterGas + air flame
---------------- >
carbon dioxide, carbon monox-The main combustion products are
ide, water, and soot (carbon).
When the burning process goes quickly, a lot of tar and highly
a lot of heat is freed quickflammable gases are produced and
ly. Little charcoal is produced in that case. if burning is nearslow (for example, if there is little air and little heat
the wood surface), then more carbon dioxide, water vapor, and
charcoal are produced. Heat is given out at a much slower, more
constant rate.
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How heat is transferred
Heat is transferred in three ways: by conduction, by radiation, and by convection. Heat is transferred within the wood by conduction, from the flame to the wood by radiation, and from the hot gases to the wood by convection (see Figure 2).
Conduction
Conduction is the passage of heat through a substance, from a hot area to a cold area. If one end of a substance is heated, that hot end contains more energy than the cold end. This energy difference is transferred through the material via the
motion of the atoms in the substance.
Some materials do not conduct heat very well. These materials are -alled insulators. Wood, air, and very porous clay bricks are relatively poor conductors of heat.
Thus a brick stove, which is a poor conductor, will take a much longer time to heat up than a steel stove, which is a good conductor of heat. The rate at which heat is transferred through a material depends on: (1) thze temperature difference, (2) the area that is being heated and cooled, (3) the ability of the material to conduct heat, and (4) the thickness of the material.
Radiation
All bodies above absolute zero temperature give off energy in the form of heat radiation. When heat radiation comes into contact with a solid, it is reflected, absorbed, or transmitted to the solid.
A body gives off radiation over a range of wavelengths, and reaches a peak intensity at a particular wavelength for a given temperature. Radiation is given off at low temperatures mainly
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spectrum. It is therefore not visible. As thein the infrared
more and more of the radiation is giventemperature increases,
off at wavelengths in the visible spectrum. Thus, while we
cannot see the heat radiation from a hot cooking pot and may bricks glowingburn ourselves if we touch it, we can see in a
kiln. The amount of radiation received from a surface that is
giving off radiation decreases rapidly with distance from the
source.
Wood gives out a luminous, yellow flame when it burns. The
power to radiate heat is very high in luminous flames because
the flame consists mainly of burning black carbon particles.
Burning carbon gives out a brighter light than burning gases.
As the number of carbon particles being given off decreases, so
does the flame's power to give off heat. The blue flame given
off by burning charcoal has a much lower ability to give off
heat radiation than does the yellow flame of burning wood. Hot
wood also radiates heat, as do the walls of the combustion
chamber. Each piece of cold wood absorbs radiation from any
surface of a higher temperature--from the combustion chamber
walls, from the flame, and from other pieces of wood. The outer
surface of the walls will also give off radiation to the
outside.
Radiation is by far the most common way in which heat is trans
ferred within a fire chamber.
Convection
Convection involves the transport of heat by the movement of
some sort of fluid, such as air or water.
Air in a room heated from the radiation of a fire moves up
ward. Colder, heavier, denser air moves in to take its place.
In this case, the hot air has moved only because of its own
natural buoyancy. The hot air is lighter and less dense than
the cold air. This type of heat transfer is called natural convection. It is this buoyancy effect that causes heated air
to leave a stove or fireplace. Buoyancy also permits colder air
to enter and supply the oxygen needed for combustion.
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On the other hand, if air is forced into a fireplace by the
wind or a blower, heat is transferred by forced convection or
advection. This also accounts for the large loss of heat from a
pot sitting on an open fire on a windy day. Even though wind is
a natural phenomenon, the convection produced by wind is called "forced" convection because it is not induced by buoyancy.
Note: For a discussion of the characteristics of wood, includ
ing factors which affect the efficiency of wood combustion,
see 5. HOW TO USE STOVES EFFICIENTLY.
How heat is contained
The simple act of enclosing a fire and thus controlling the
amount of air fed into it greatly affects the intensity of the
heat and the efficiency of the burning process. A cooking fire
that is enclosed in some way becomes a stove.
Stove components
The most basic wood-burning cook stove is an open fire circled by a few rocks or by bits of brick. A pot is balanced on the rocks. This basic stove is unsatisfactory for the following reasons:
a It is very wasteful of fuel.
0 The temperature is difficult to regulate.
a Smoke from the fire can cause or worsen eye and respiratory problems, and can leave cooking areas black with soot.
a Burns and scalds are a danger, especially for babies and small children.
In some areas, the efficiency of this type of fire has been
increased greatly by simply building walls almost completely
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around the fire. The top is covered with some kind of grating
upon which the pot is placed. While this does not help a great
deal with the smoke problem, it can result in substantial fuel
savings.
Adding a flue or chimney (described below) and a draft control
further increases fuel efficiency, helps in temperature con
trol, and stops much of the smoke problem. An improved cook
stove can be made from a variety of designs, using many differ
ent types of materials. Fired bricks, sun-dried clay blocks,
clay/sand mixtures, and sheet metal have all been used to make
improved cook stoves (see Improving Traditional Stoves, which
follows this section).
Sevaral basic components are common to all improved stoves:
* firebox * flue or chimney * air inlet * one or more dampers * baffles * heat exchangers
Firebox
The chamber in which the initial combustion takes place and the
fuel is burned is the firebox. Some stoves may also contain a
secondary firebox where many of the gases produced by the ini
tial combustion are burned. There should be no uncontrolled points of entry for air in the firebox.
Chimney or Flue
The chimney, or flue, is the passage by which the gases and smoke leave the fire. The function of the chimney is to draw
water vapor and smoke out of the kitchen and to create a pres
sure difference so that air is drawn into the firebox. The
words "chimney" and "flue" are often used interchangeably. Some
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people interpret "flue" to mean only the passageway between the
firebox and the chimney. To others, the "flue" is the passage
way in the chimney.
The chimney commonly extends upward from the stove a distance
of 1-3/4 to 2-1/2m (6' to 8')--or more. This distance varies
with the type of stove and can best be determined by experimen
tation. Some stoves simply will not burn well until a certain
chimney height is reached. To find the best height, one can
either start small and add sections, or start tall and take
away sections. The top of the chimney should be about 3/4m
(30") above the highest point of the roof. This is for both
safety and preventing downdrafts from forcing smoke back into
the stove. Downdrafts sometimes occur around buildings.
The diameter of the chimney is also variable. There are equa
tions that can be worked out taking into account the size of
the firebox, height of the flue, etc. But in a practical situa
tion, chimney diameter will probably be determined by what is
available at the lowest cost. Often this will be 10cm (4") gal
vanized stovepipe. For the range of designs presented in this
manual, that size pipe is perfectly adequate.
The chimney should have a cap on it to prevent rainwater from
washing into the stove. It may also require a spark guard--a little screen cage--to prevent sparks from flying out onto
flammable roofing material. Both cap and guard should be removable to permit easy cleaning of the chimney. This is very important.
The chimney must be cleaned regularly. As the hot gases and
vapors cool, some substances condense and collect on the inside of the flue. One of those condensates is creosote, a dark,
sticky, very flammable material. A heavy buildup of creosote
can clog the chimney. Worse, it can catch fire from a flying
spark. Creosote deposits can be burned off in the early stages by building a very hot fire in the stove. Or they can be
removed by cleaning the chimney at least every six months. This
can be done with a long-handled brush, or with a bundle of sticks and rags attached to a long pole.
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A metal chimney will lose heat faster, and thus be more prone
to a creosote buildup than will a clay or masonry chimney. Gal
vanized metal is preferred over blued metal by some people. In
some places, work has been done with a material that might be
called "ferromud6--a form made of chicken wire, plastered with
clay to form a strong chimney. "Ferromud" may be significantly
cheaper than either metal or clay chimney pipe.
Air Inlet
The fuel must have oxygen to burn. Air is fed into the firebox
through an air inlet and then sucked through the fuel by the
draft created by the flue or chimney. Because a strong draft
causes a hot fire, an efficient stove will have an adjustable
opening to allow the cook to control the rate of burning, and
thus to control the temperature.
Dampers
A damper is a movable plate which controls the draft. One or
more dampers can be used to control the flow of air. Placement
and operation of the dampers depend on the design and construc
tion material of the stove. If only one damper is used or
needed, it should be placed at the mouth of the air inlet. A
second damper can be placed at the end of the stove portion of
the flue, just before it bends upward. Sometimes sections of
commercial stovepipe are available which have dampers built
in. A very large stove may require additional dampers to prevent the hot gases from reaching unused areas of the stove.
The damper can be made of metal or blocks of clay or stone. It must fit very snugly so that it can block the flow of air com
pletely. Sheet metal especially will be hot to the touch, so
some kind of relatively cool handle should be provided.
Baffle
In a chula-type stove, like most of the ones in this manual, a baffle is a mound or step molded into the tunnel. A baffle or a
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series of baffles serves two purposes. It prevents the direct escape of the hot gases, allowing them to burn more completely. And a carefully placed baffle redirects the flow of the hot gases around the pot and increases the time the pot is exposed to the heat.
Baffles can be placed at the exit of the combustion chamber. Here they will redirect the flame and gases back onto the surface of the wood. These baffles also redirect the flame and gases under the pot surfaces. This heats the pots faster. Food cooks more quickly.
Baffles can also be placed in the flue. Here they will help keep the hot gases near the second and third pots. More heat is transferred to the pots. The food cooks more quickly.
ITDG has done tests that show that baffles can decrease wood use by 50 percent when placed correctly.
Heat Exchanger
The heat exchangers in most of the stoves discussed in this manual are the pots themselves. These will vary from community to community and are as individual as the foods cooked in them. In Guatemala, cooking pots are often rounded clay vessels with relatively small necks. Cooks in many parts of the Sahel use round, open, iron kettles, while pots of aluminum or brass may be used in India.
Traditionalstoves
Three Stones
The most basic, and one of the most common, wood-burning cook stove is simply three stones arranged on the ground in a triangle (see Figure 3). Use of this stove differs from region to region. One of the more efficient ways of using it will now be examined in detail.
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Figure 3
The fire is started with kindling. Once the kindling is burning, large pieces of wood are placed between the stones. A pot is then balanced on the stones. The amount of heat given off by the burning wood can be increased or decreased by moving the wood further into or further away from the center of the stones. After a short period of time the stones become heated to at least 300 0-500 0C 1556 0-932 0 F). These hot stones absorb heat and also transfer some of it back to the fire, the pot, and the incoming air. This air also has to pass through the hot gaseous products of combustion. Thus the air is preheated and can therefore react more easily with the wood gases at the glowing ends of the sticks. So in the middle of the fire there is a very hot region with continual movement of hot gases out and the intake of colder air. Now, the energy to sustain the combustion of a piece of wood comes from both radiation from the flame and from the glowing tips of the other pieces of wood. As the pieces of wood are moved apart, the energy absorbed by any one piece decreases. Thus the rate of productivity of gases, tar, and charcoal decreases and therefore the total rate of heat released by the wood also decreases.
Three-stone cookers have a number of drawbacks. The pot loses large amounts of heat by convection, particularly if it is exposed to any breeze. The hot gases produced in the fire quickly spread away from the cooking vessel, so very little of their heat energy is transferred to the pot. If the wind is
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blowing, these gases dissipate more quickly and even less of their energy is transferred. If the pot is placed very close to the seat of the flame, much soot and tar is formed; the relatively cold surface of the pot may lower the temperature of the gases below the ignition point. The smoke and danger of burns and spilling from pots are also drawbacks, as is the discomfort of cooking on the ground.
Chulas
In many parts of southern Asia a mud stove known as a chula is widely used. There are many different versions of the chula. Probably the most common version is illustrated in Figure 4.
Figure4
This stove consists of a hollow box with an opening at one end for inserting the wood, and a number of holes on top which allow cooking pots to be placed over the fire. The smoke escapes around the pot and out of the entrance. Under some conditions these stoves are less efficient than the three stones
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configuration. Goldemberq and Brown (1979) have shown that the cooking pots absorb only a small percentage of the heat radiation emitted by the fire. But heat escaping up around the pot heats its sides fairly effectively-by conduction. As the air enters the chula, it tends to flow over the top of the wood, not through or around it. Thus, much of this cold air flows directly into the flame zone. The large amount of excess air tends to lower the flame temperature and to prevent the ignition of the volatile wood gases.
A widely used chula that burns scrap wood and straw (see Figure 5) is found in Bangladesh. This stove is constructed in the ground and consists of two holes linked together. Around the larger hole are three raised points on which the pot is placed. Scraps of wood and waste are placed in the hole and lit. Air is drawn down the hole and mixes with the fuel. The flame and smoke are drawn up through the space between the pot and the pot stand.
/ , Figure5
A more portable but less efficient version of this stove is seen in Figure 6. The stove is made by artisans from clay and dung, and is sold in the marketplace. Wood is placed through
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23
the large hole and sits in the bottom of the stove. Visual
observations indicate that only part of the incoming air is
actually drawn down to where the wood is burning.
Figure 6
Stoves in Asia have been designed to burn rice hulls or saw
'ust. One widely used type is made of fired clay, with an inner
spout that has been perforated. Rice hulls are placed in the
spout. Burning twigs and paper are placed underneath. The heat
from this burning material causes the rice hulls to catch fire.
There is a sawdust burning stove in northern Bali, Indonesia,
that is built of adobe brick. Mud is plastered over the
outside.
Kamado-style Cooker
The traditional Japanese earthenware cooker, the Kamado, can
serve as a design model easily adapted to the village situa
tion (see Figure 7). Made almost entirely of ceramic, the
Kamado consists of an outer insulating shell that holds a
removable firebox and grate. A metal grill--the only non
ceramic part--sits on a ceramic ring that holds pot and food
above the fire. A hinged lid allows the stove to be used open
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24
or closed, permitting baking, boiling, frying, and barbecuie
g. The double-walled design of firebox within shell, as well
as the ceramic material itself, serve to minimize heat conduc
tion to the surrounding area. The temperature is controlled by
adjusting the top damper and bottom damper to regulate the
draft.
Figure 7
A 20-liter (5-gallon) drum or sheet metal cylinder can be sub
stituted for the ceramic outer shell, though it will not pos
sess the insulating capability of the original. The ceramic
firebox and grate can be made locally in simple disc and cylin
der shapes. They do not require firing in a high temperature
kiln to be used in the stove.
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25
Simple metal stoves
Metal containers of approximately 20-liter (5-gallon) size can form the basis for several simple stoves.
Rice Hull Stove
A small oil druL or other metal container, .,r a structure made
of brick, forms the fuel chamber for rice hills or sawdust. An
air vent is made in the side of the containe. at the bottom. A
6cm (2-1/2") stick of wood is placed on the floor of the
container through the vent hole. Another 6cm (2-1/2") thick piece of wood is placed in the center of the container so that it touches the end of the stick lying on the bottom.
Rice hulls or sawdust are poured around and over the two sticks and packed firmly with a block of wood. The chamber is filled to about 5cm (2") from the top. The two sticks are carefully removed, leaving a tunnel through the fuel from the air vent to the top.
Sawdust Cook Stove
This stove is used to burn sawdust. It is very similar to the rice hull stove. It is made from a tin can approximately 25cm X 25cm (10" X 10"). A circular hole 10cm (4") in diameter is cut near the bottom of the tin. The inside of the tin is plastered with clay and cement 3cm (1 .1/4") thick. Two bottles ark. laced inside the cooker and . , space around them is filled with sawdust (see Figure 8). The bottles are then removed. Iron or steel rods or straps are placed across the top of the container to support the cooking vessel.
Figure 8
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26
To light the fuel, a piece of firewood ab.)ut half the thickness
of the bottles used to form the air openings is used. This nar
row stick is dipped in kerosene, set alight, and then carefully
pushed, while still burning, into the air channel from the air
vent (see Figure 9). When the fuel begins to burn, the pot is
placed on the supports and the stove is ready for cooking (see
Figure 10).
Figure 9 Figure 10
As the firewood burns, it is slowly pushed further into the opening. A lm (39") length of wood, 2cm (3/4") in diameter, and a full chamber of sawdust are said to provide a cooking flame for two hours' cooking.
The air enters at the bot
0 n tom of the hot inner casing, where it is heated. It then passes over the surface of
the waste. The fuel burns outward leaving an onion
ji shaped cavity (Figure 11).
Figure 11
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27
Stove-in-a-bucket
A small, experimental cook stove consists of a commercially
available galvanized metal bucket fitted with two gi..tes (see
Figure 12). One grate fits inside the bucket about 15-1/4cm (6") from the rim. This grate supports charcoal or firewood. The second grate goes on top of the bucket. 00 0
Food is cooked here--either in a pot or grilled directly over the coals. This stove has not
been field tested, but would probably be short lived. 0 o oo
Figure 12
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3. HOW TO MAKE STOVES EFFICIENT
The efficiency of a stove depends on many factors, from the
design of the stove to the type of fuel used. This section discusses the ways in which energy losses can be reduced by improving the designs and the materials of traditional stoves.
Conserving heat
Energy lossesin stoves
Only part of the wood's chemical energy can be used to cook food or provide heat. Losses occur due to:
Incomplete combustion. Some of the volatile gases and charcoal produced during the burning process do not react with
the incoming oxygen; thus, the heat that would be generated by these reactions is lost. Incomplete combustion leads to
the formation of soot and tar particles in the gas stream leaving the combustion zone. It can also lead to the formation of carbon monoxide, which may accumulate to a dangerous level in the living quarters.
* Heat carried away by the gases produced by combustion. The gases leaving the combustion zone are hot. Unless the pot
can capture this heat, it is lost to the atmosphere. These gases also contain air. The greater the percentage of excess
air (that is, the amount of air beyond that required to burn
the wood completely), the greater the heat loss to the gas
stream will be. Some heat energy is needed to exhaust flue gases and draw in combustion air.
Losses due to heating a stove. The stove absorbs heat from
the fire. Some of this heat will be transferred to the pot, but some is lost.
29
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30
" Losses to the atmosphere from the stove walls and the cooking pot. Any hot object will radiate and conduct-heat to
anything cooler around it.
. Energy used in evaporating excess water from wood with high moisture content.
" Inefficient operation of the dtove for intended purpose. Examples. Having a high draft to allow faster cooking. Not using pot covers while cooking. Using wood pieces that are too large or too small.
The first four losses can be minimized through proper stove design.
Improving combustionefficiency
As discussed previously, wood burns efficiently if there is
enough, but not too much, air. There should be a temperature of about 5000 to 600 0 C (9320 to 11120 F) around the wood surface. High temperatures can be achieved by:
insulating the fire box (combustion chamber);
reflecting part of the heat absorbed by the walls back onto the wood surface (Figure 13);
Figure 13
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31
. placinq the pot away from the seat of the fire. The most
efficient position for the pot is where the flame is not
cooled by the pot's cold surface, but where the bottom of the pot still receives a large proportion of the radiant
energy released from the fire;
. controlling the flow of cold air to the fire.
Air can be channeled around the wood by the use of grates or
baffles. There are five ways that the air can be forced to flow
through the wood (see Figure 14).
UP DoL,4 CROSS 'N DRAFT DRAPT OPAFT oPAwr C9AFT
Figure 14
There is no evidence to date to show that any one of these
designs is the best. However, it is known (Winkelman, 1953)
that if a grate is used, the walls of the combustion chamber must slope in toward the grate (Figure 15), and that the area
of the grate open to the passage of air must be approximately 25 to 30 percent of the total grate area.
Figure15
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32
More sophisticated methods of improving combustion efficiency are:
* recirculating the flue gases * preheating the primary air * adding secondary air at the end of the flame zone (Figure
16).
Figure 16
Using the heat from the gas stream
The gases produced from the burning of wood in open fires escape almost immediately to the atmosphere. If these gases are
taken from the combustion zone via the flue and passed around a pot, heat will be transferred from the gas stream to the colder pot. The longer the gases remain in contact with the pot and the more turbulent the motion of the gases, the greater will be
the heat transferred. However, if too much heat is taken from these waste gases, water and creosote will condense out. Creo
sote can catch fire in the stove, and water causes corrosion of any metal stove parts.
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33
Minimizingheat lossfrom heating the stove
to heat a stove can be minimized in two The heat required
ways. If food is to be cooked quickly, or once or twice a day,
or of a material the stove should be designed with thin walls
absorb much heat. If cooking is done that does not readily
frequently throughout the day, a stove that has a thick wall
well should be constructed. This stove will and holds heat
heat from the fire always remain hot. When cooking, much less
will be absorbed by these hot walls.
Minimizing heat losses from potsand stove walls
the Losses from pots can be minimized by heating the
pots to
boiling point very quickly, and by preventing a draft from
stream flowing around the pot. Setting the pot in the
hot gas
if the pot
can prevent drafts. Considerably less heat is lost
a tight-fitting lid. A flat-bottomed pot captures radiant
has
the round
heat more efficiently than a round pot. However,
capture heat more efficiently when thetobottomed pot seems
form of heat transfer is via convection. Pots made
of main
metal transfer heat much faster than earthenware pots.
The amount of heat lost from a stove depends on the outer wall
temperature of the stove and the speed of the air flowing past
the stove. The closer the stove wall temperature is to the sur
rounding air temperature and the lower the speed of air flowing
are the losses. Heat losses from past the stove, the lower
stove walls can be lowered with some stoves by a double wall or
brick lining.
Improving traditional stoves improving any stove to lookIt is important before adapting or
at the social and cultural functions that stoves perform in the
used. Some seemingly laborious orsociety in which they will ?ie
significance. Newinefficient practice may have great social
to the local traditionalstove designs should also be adapted
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34
cooking customs, cooking pots, and the types of food to be cooked.
Designers have followed two approaches in improving traditional stoves: combustion chamber engineering and the chimney-anddamper approach.
Combustionchamber engineering
This involves modifying a traditional stove by insulating the firebox, changing the shape of the combustion chamber, or other means. This is the most recent approach being pursued by several organizations, including the Intermediate Technology Development Group (ITDG) of England. None of these stoves has been field using
tested. However, this method are
initial results very promising.
for stoves A few case
designed studies
follow.
The Bangladesh chula--Dr. Nuruzzaman of the Bangladesh Council of Scientific and Industrial Research is carrying out work on this stove. Dr. Nuruzzaman observed incomplete burning of the wood in the bottom of the stove. Using a thermocouple, he measured the vertical distribution of temperature down the center of the stove. He inserted a ceramic grate at the hottest placeand put the wood on this grate. He fou-nd that the amount of wood required to boil water was considerably reduced.
Thai stove--While this is a charcoal-burning stove, the design principles used can be relevant to designers of wood-burning stoves. Keith Openshaw greatly reduced the amount of charcoal used and the amount of time required to prepare a meal on a traditional metal charcoal burner used in Tanzania. To improve this stove, he decided to insulate the sides, make them slope inward, and improve the distribution of air around the char- MO coal. Openshaw found that a stove manufactured in Thailand met his requirements (see Figure 17).
F~gur 17
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35
He provides the following description of the stove:
The clay stove described here originated in Thailand. It
although it may be purchasedusually has three layers,
and middle ash layer. It iswithout the outer metal cover
made almost entirely of local materials--clay and ash. Only
the outer metal is paid for in foreign exchange. This outer
is to the more durability. It ismetal cover give stove
such as are used forgenerally made from old tin cans
with ash (ricepacking fruit. The middle layer is filled
and has a simple cementstraw ash in this particular case),
inner layer is made of burntseal to contain the ash. The
top, tapering to about lcm atclay about 3cm thick at the
fire is made of the same burnt claythe base. The grate
cement. If the grate breaks, itmaterial and secured with
stove. It is can be replaced without the need to buy a new
extra grates at the time ofusual to buy one or two
purchase. The air space in the grate is about 25 percent of
the total area of the base, as compared to about 10 percent
of the design featuresin the metal stove. This could be one
that make this type of stove more efficient. The clay stove
has a larger diameter at the top than at the base and this
It was noticed thatacts as a kind of self-stoking device.
unlike the metal stove, the charcoal never had to be moved good designaround to obtain a complete burn, another
has raised platformsfeature. The rim of the stove three
which support the pots and pans, and three depressions which
inflow air the supplement the airallow an of at top to
inflow at the base. The air intake at the base does not have
a door, but it may be restricted by using a brick. Again
but the dimensions shown inthere are various stove sizes,
Figure 17 are typical for household use.
took half asIn field tests Openshaw found that this Thai stove
the metal equivalent.much charcoal to boil water as
Dr. de Lepeliere's metal stove--This stove was designed for use
in Africa. The stove was initially constructed from metal. It
a 450 angle. Thehas an inner combustion chamber that slopes at
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36
chamber has a number of holes around the outside. The combustion chamber sits inside a metal outer casing. The pot is placed inside, halfway down this outer casing (see Figure 18).
Figure 18
The air enters through the outer casing and absorbs heat from the hot inner chamber. This preheated air then enters through
the inlet holes around the fuel. The incoming air serves effectively as an insulating layer between the combustion chamber and the outside. The heat that is lost from the fire is partially reintroduced by the incoming air.
Heat is transferred to the pot both by radiation from the fire and by convection as the hot gases flow around it as they leave the stove. When the water in the pot has boiled, the rate of
heat released can be lowered by placing mud over part of the inlet hole.
The main disadvantage of this stove is that it requires fuelwood cut into small pieces.
ITDG stove--Two traditional Indian stoves were joined to make this stove. Still quite new, the stove has not yet been field
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37
designed to be portable,. built by localtested. The stove was
craftspeople, and used for both cooking and baking (Figure 19).
Figure 19
The stove consists of two sections: a hollow box similar to the
chula described on page 21, and an oven, or Tandoor. A grate is
placed inside the firebox under the area where the first pot
towards its front, allowing the rests. The firebox is narrow
into it continuwood to serve as its own damper. Wood is fed
ously. The heat released depends on the length of the wood
over the grate. The cooking port is designed to hold thelying
hot plates used for making chapatis, or to hold round-bottomed
the inlet airpots. The fire can be controlled by covering
hole.
A small baffle is placed at the other end of the firebox. Gases
and flame enter the Tandoor parallel to its walls. There is a
great deal of turbulence in this region, and most of the vola
tars react with the oxygen to form a verytile wood gases and clean gas composed mainly of carbon dioxide and water vapor.
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38
The hot gases then circulate around the lower wall and around the pot that has been placed in the outlet. Heat is transferred both to the pot and to the walls of the Tandoor. Depending on the length of time that the stove has been in use, the residual heat can be used to bake bread.
The chitr&.y-and.damperapproach
Much of the earlier work carried out to improve traditional stoves was based on the development of airtight stoves in European countries. Two features distinguish these stoves from those just described:
* the ability to restrict the air entering the stove ato
single place; and
" the use of a long pipe or chimney to take the combustion products away from the stove a: supply the necessary pressure forces to cause the air to enter the stove.
All of these stoves have the same basic components: an air and wood inlet, an airtight combustion chamber or firebox, chimney, heating surfaces, and adjoining flues.
Air and wood inlet--Except in some updraft stoves, wood and air enter through the same opening. The air is controlled by a damper at the front of the stove or at the back of the firebox or flue. If the damper is placed at the back, wood can be fed in continuously.
Airtight combustion chamber or firebox--See HOW TO MAKE STOVES EFFICIENT, Improving Combustion Efficiency.
Chimney--The function of the chimney is to draw water vapor and smoke out of the kitchen and to create a pressure difference so that air is drawn into the firebox.
The chimney can be made from clay pipes, sheet metal, cast iron, masonry, concrete pipes, bamboo, and so on. Brick or clay
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39
than sheet metal chimneys. The pipes will 1have a longer life
length and diameter of a chimney are very important. The bigger
the size of the chimney. If the stove, the greater should be
will not be able to the chimney is not big enough, the stove
operate at maximum efficiency. However,draw in enough air to
is tQo big, the stove may be difficult to if the chimney
increased. The maximum amount operate and heat losses will be
can be altered much moreof air that enters the stove
the chimney than byeffectively by changing the diameter of
to have a diameterits length. It is advisable notchanging
cold air could flow back down greater than 15-1/4cm (6"), as
out
the chimney. The height and diameter can be worked
and error is sufficient in mosttheoretically; however, trial
chimney is controlled byfield situations. The length of the
the highestit should be higher thanthe height of the house;
point of the roof.
a roof (especially one made of When placing a chimney through
to place a metal thimble around the thatch) it is advisable
may be used as a thimble (see Figure 20).chimney. A tin can
Figure 20
must be cleaned regularly to prevent fires. HowThe chiitney
how hot theoften the chimney needs to be cleaned depends on
the wood, and how much water was instack gets, how green was
to
the fuel. Normally the chimney would need cleaning every one
six months.
-
Heating surfaces and adjoining flues--There are two basic designs for transferring the wood's energy to the pots and for transferring the gases from the firebox to the outside of the house.
The most widely used design for European cooking stoves is shown in Figure 21. One or two pots are positioned over the firebox and the other pots are placed over a second chamber that adjoins the firebox. Flames touch these pots when the damper on the air inlet is fully open. The pots also receive heat from the hot top plate that covers the stove. Waste gasesusually flow past the oven and up the chimney. The sides and bottom of this stove are insulated.
Figure 21
An alternative design (see Figure 22) that has been tested byITDG has proved reasonably successful. A checkerboard of bricks
is placed in the second chamber. When the stove is operating at high heat the waste gases transfer their heat to these bricks. When the fire dies down tiese hot bricks reradiate the stored heat to the pots.
Figure22
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41
21 made from sheet metal has been A simpler version of Figure 23). The combusionDr. de Lepeliere (see Figuredesigned by
chamber has been shaped to accommodate long pieces of wood. Air
stove. Both potscombustion chamber underneath theenters the
receive heat radiated from the flame. The hot
flue gases also
they pass aroundof their heat via convection astransfer some
the two pots. All of the stove's surfaces, however, become very
room. Also, it is difficult to hot and radiate heat into the
remove the pots from the stove.
InI
Figure23
type of design was developed in India in the 1950s
The second
Research Laboratory (see Figureby the Hyderabad Engineering
was based on trathe HERL or smokeless chula, it24). Known as
ditional Indian chulas and adapted by S.P. Raju,
former directhe
tor of the laboratory. Today it forms the basis of many of
stove designs being promoted throughout the world.
bricks and The HERL chula is basically an "L" shaped block
of
horizon
mud, with holes on top for cooking pots. A tunnel runs
of theThe fire is built at the fronttally through the stove.
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42
Figure 24
tunnel beneath the first pot. A chimney of clay or sheet metal is installed at the other end. Hot gases and flames flow
through the tunnel, under the pots, and up the chimney. A
damper provides draft control. The number af pot holes and the
size and height of the stove can be adjusted to the user's needs.
Some possible drawbacks of this type of stove are:
It is not portable.
The damper must be used properly if there is to be a marked saving in fuel consumption.
To use this stove efficiently, the three cooking ports must
be covered. When three pots cover the holes, the first two
will gain heat fairly rapidly, while the third will take a
longer time to heat up. The efficiency of the stove decreases markedly if the cooking holes are not covered. Should the
family want to cook only one or two dishes, covers need to be placed over unused cooking holes.
Much of the wood's energy is used in heating the stove in the heavier models. It is advisable not to let these stoves
cool down. Regular use during the day will achieve this end.
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43
use. The stove will produceThese stoves can be dangerous to
is closed.
carbon monoxide when the damper of the air inlet
The occupants could be poisoned if this carbon monoxide
escapes to a poorly ventilated room.
and smokearound the cooking holes. Heat Cracks can form
not mended regularly.will escape if these cracks are
are included in Two successful adaptations of the HERL chula
Lorena stove (see
this manual: the Singer stove and the
rely on the same TO BUILD FOUR STOVES). Both stoves4. HOW
a tunnel carrying hot gases beneath basic design element, i.e.,
and past the pots, and the addition of a chimney. Both stoves
basic chula has been adapted to suit are examples of how the
to utilize available buildinglocal cooking preferences and
stove is assembled from smaller blocks. materials. The Singer
The Lorena stove is built from a massive sand and clay block.
the Singer
The Lorena stove's design concepts differ from
both
and the HERL stoves in the following ways:
The front damper controls not only how much oxygen is avail
it strikes theable, but where it is available and how fast response. It can bebed of coals. This gives it a very fast
and can be damped downfired up very quickly from coals,
that it can burn material more gradually. It also means
such as sawdust, bark,which is not easily combustible,
corncobs and, possibly, peat.
a newof sand (up to 85 percent) creates" The proportion material that is neither adobe, clay, nor brick.
This mater
concrete.ial has a strength property near that of
is sometimes an advantage.The great mass of a Lorena stove*
It enables the stove to absorb a greal deal of
heat. This
low. The stove shouldmakes the chimney temperature very
have a long, circuitous tunnel system for it to work well.
Of the three stoves discussed, the Lorena stove has found the
widest acceptance. Recent work in Nepal has shown that it uses
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44
much less wood than the HERL chula. Work; is continuing on its development. Details of improved versions are being
published regularly by Volunteers in Asia and by the Aprovecho Institute.
Because monolithic and brick stoves cannot be moved, some work has been carried out on the design of a ceramic stove that can be assembled in one place and then transported to the place in which it will be used. This stove, the portable
Magan Chula (see Figure 25), has been designed, built, and disseminated by the Gandhiniketan Ashram. It consists of a number of single ovens that serve as pot seats, and a chimney base and round flues that connect the ovens. These are all made by a potter, either by hand or on a wheel. Holes
are provided in the side walls of the ovens for the linkpipes that join one oven to another, and the last oven to the chimney. The various parts are assembled in the home. Each joint is secured and made airtight wi'h mud. A baffle is placed 1ia the middle to help promote heat transfer once the ovens have been joined. The passages connecting the first pot seat to the second and third incline upward toward the
Figure25 chimney base. This mproves the stove's performance.
Improved mud stoves have also been adapted to burn agricultural waste and sawdust. The waste is burned on a step grate
placed inside the stove. The waste is fed from a hopper onto this grate. These stoves are used widely throughout Asia. They c Ln be constructed from adobe bricks, heat resistant cement, steel, or ceramic material. The grate is usually
inclined at a 450 angle. The percentage area of the grate
that is open is 25-40 percent of the total grate area (see Figure 26).
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45
Figure26
The efficiency of these stoves is affected by the rate at which
fuel is fed into them. Mukhopadhuay found that the maximum heat
occurred at a feed rate of 3.5kg/hr for a stove with a grate
there is little information on the area of 570cm 2 . As yet,
effect of changing the size and shape of the firebox and flues.
A step grate stove being disseminated throughout the Philip-
Ipa stove (see Figure 27). It is constructed ofpines is the
adobe blocks with a cement top. The chimney is made from sheet
steel. The cooking holes have cast iron covers.
Figure27
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46
These stoves have also been widely modified for use in food processing. Figure 28 shows a stove used by 'gula jawa' coconut sugar producers in Blitar, East Java. It uses rice hulls for fuel. At 3,500 Indonesian rupiahs (about $8 US), this is one of the cheapest natural draft stoves available. Clay mortar is used rather than cement. The l-1/2m (5') chimney draws flames back to the last pot, l-1/4m (4-1/2') from the burning hulls in the grate. The floor slants slightly upward toward the back of the stove to increase the draft. The grate is a piece of perforated iron sheet placed almost vertically in the mouth of the stove. There is some evidence that this type of grate is as efficient as a step grate (Bruce Lamb, 1979). The stove will not operate with the pots removed. When the pots are replaced, air leaks around the edges are simply patched with a mixture of mud and rice hull ash.
Figure 28
The pot nearest the fire is the hottest, and the one nearest the chimney is the coolest. This is especially well suited to the process of cooking gula jawa, as different temperatures are required at different stages of the process. The temperatures of the pots range from a fast to a slow boil.
This stove is used daily to boil down 50 liters (about 30 gallons) of coconut sap to 7kg (about 3-1/2 lb) of light brown sugar cake. This requires half a gunny sack (about 6kg 3 lb]) of rice hulls daily, burned over a period of four hours.
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47
J.C. Overhaarte of the Technische Hogeschool, Eindhoven, The
stove that is portable andNetherlands, has designed a metal
and small pieces of wood. Primary air entersburns both waste
through four cylinders into the middle of the combustion cham
ber. A pot sits on top of the firebox. The hot gases flow
underneath the pot and around the firebox. The gases transmit
some of their heat to both the primary air inlets and to a
on the base of the stove. This stovesecond pot that is placed
of heat, but would not have a lifetime ofwould radiate &,lot
more than 12 months in humid conditions.
Another stove (see Figure 29),
made from a small oil drum, is
reported to use half of the
fuel that an open fire would The edges around the use.
firebox door are bent back to
avoid the danger of cut
fingers.
FIgure29
Improving stove building materials a stove depend on theThe efficiency, safety, and durability of
a mudmaterials and construction skills used. For example,
stove with cracks around the firebox or cooking holes will let
heat out. Smoke and poisonous gases may escape into the room.
Cast iron, steelplate and sheet metal
Most stoves produced in Europe and America are made of cast [about 1/10"] thick). Theyiron or sheet plate (at least 34mm
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48
last a long time (at least five years) and are very good conductors and radiators of heat. They can be produced in a small workshop or foundry, but are expensive to make and require considerable care in their construction if they are, to be airtight. These stoves are mainly used for heating, and must be insulated using a refractory brick if they are to 'be used for cooking only. To date only one cast iron stove has been produced specifically for Third World countries. There is no information available on its performance or cost. Cast iron cooking surfaces are available in the developing world, however. These stoves often have removable rings so that pots of different sizes can be used.
Sheet steel stoves are used widely in both developed and developing countries. There are some important ways in which these stoves can be improved--without increasing production costs.
Corrosion of the steel can be inhibited by using a stove enamel or by lining the stove with clay. 1 This will increase the life of the stove.
Traditional methods of fabrication can be improved, resulting in airtight stoves of a more efficient design. Ole Wike's book,
IRicholson (1979) gives this formula for stove polish:
US Metric
Graphite 1 pound 453.6 gm
Lamp Black I ounce 28.4 gm Rosin 4 ounces 113.4 gm Turpentine 1 gallon 3.8 liters
Richolson modified the formula for Rijian conditions by substituting kauri gum (Kadua makadre) for rosin and by using a mixture of turpentine and methyl alcohol in equal parts to dissolve the gum. The gum also appearedsoluble in ethyl alcohol, but not in either methyl alcohol or turpentinealone. Carbon cores from spent flashlight batteries can be used for graphite. The stove polish should be rubbed into the surface of the steel regularly after the stove has been used to slow corrosion.
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49
Wood Stoves: How to Make and Use Them, is recommended for those
wishing to improve traditional sheet steel stoves.
Ceramic
cooking vessels. The potsMany societies use fired clay pots as
are made by local craftspeople. However, with the introduction
of steel and aluminum pots, the need for these craftspeople is
diminishing. Another source of revenue for them could be pro
vided by the production of fired clay stoves..
Pottery is not a material that withstands uneven heating or
constant heating and cooling. When designing a pottery stove,
care must be taken to:
Make the clay very open. This can be achieved by adding saw
dust, or material fibers and crushed brick, or discarded
fired pottery (grog).
2 Use clays that can withstand heat.
or sheet.Reinforce the outside of the stove with steel wire
Line the inside of the stove with a heat resistant lining.
Pottery stoves heat up very quickly, are portable, and do not
take nearly as long to construct as mud stoves.
Mud and brick
"Mud" stoves are traditional in many areas. The mud is usually
soil with a high clay content, mixed with cow dung, straw,
sand, etc.
2At present this is generally ascertained through trial and error. However, work is being carried out by ITDG and collaborating organizations to develop materials that can be added to clay to improve its refractory properties. The results of this work will be published in the near future.
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50
Different soils have different properties. Before a mud stove is made, the local soil should be tested. If it does not have the right proportion of clay to sand (about 20 to 30 percent clay and 70 to 80 percent sand), then extra clay or sand must be mixed in.
The Lorena stove described elsewhere in this manual is made of a
nmixture that is mostly sand. Sand does not shrink when it dries because the individual grains of sand are rigid and hold each
.Jother apart (see Figure 30). The clay is the glue needed to hold the sand grains together. Clay and sand must be mixed together
Figure 30 very thoroughly, as unmixed clay balls weaken the mix and preventit from holding together.
The lorena mix needs only three ingredients:
" a lot of sand to form the mass of the stove " a little clay to glue the sand mass together * water.
If"a pure clay soil is used, a lorena mix that is 75 to 85 percene" sand less sand
must must
be made. When also be used,
soils with especially
less clay if there
are used, is already
sand in the soil. If the soil is of the clay-silt type, the silt
does not help much, percentage should
so the remain
sand high
(see Figure 31).
Lorena ideally needs a fairly 9ND ' coarse sand and a soil with a
Figure 31 high percentage of clay. More
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51
than 60 percent clay is ideal. Avoid silty soils and soils without clay (such as volcanic ash soils and sandy soils), since these will have little or no glue power to hold the sand mass together.
One formula (Flickinger, 1979) was recently developed in
Indonesia for soils low in clay:
1/2 to 1 part wood ash a 1 part clayJ mix together with a little water
2 parts sand 3/4 part grain chaff 1 pan constarch or cassava starch
Soils with less than half clay can be used if they are already mixtures of clay and sand rather than clay and silt. Organic matter (leaves, twigs, straw or husks) in the soil creates problems, so use subsoil whenever possible. The soil used is from at least 20 to 40cm (about a foot) beneath the surface (see Figure 32).
Figure 32
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Making the correct lorena mix is very important.
With too much clay the lorena mass, as it dries, shrinks unevenly and cracks the stove.
With too much sand the lorena is too soft and the mass will fall apart.
With too much silt the sand/clay mix is diluted, causing interior tunnel surfaces to flake away in the heat of a cooking fire.
Stove builders using unfamiliar soils should first talk with a local brick or adobe maker to determine what the soil is like. One test is to make mud balls about the size of a chicken egg. Fire them in a hot fire. Check which mixture gives the hardest ball without cracking. In addition, it is recommended that a small test stove be built if the soils are unfamiliar. Test the small stove with fires for about a week =nd watch carefully for cracks, especially around the firebox. If there are no cracks after a week of use, it is fairly certain that it will not crack later.
If there is very little clay in the soil, another material will have to be found to glue the sand mass together. Experiments nave been carried out with raw sugar (it is used in building Mexican bread ovens), but more experiments with suitable glue materials are needed.
Remember that although a 1:4 lorena mix (one portion soil mixed with four portions sand) may be necessary in one place, a short distance away a 1:2 or 1:]. lorena mix may be necessary. Even two layers of soil right next to each other may have very different clay contents.
Use the following lorena mix chart as a guide for soil/sand proportions. Watch carefully for cracks in the first stove produced, and be prepared to change the mix.
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53
Soil Sand
(Percent) (Percent) Proportion
1:5 to 1:3Pure clay soils 15-25 75-85
1:3 to 1:2Clay/sand soils 25-35 65-75
65-75 1:3 to 1:2Clay/silt soils 25-35
how much clay is in a soil, take a smallTo test to find out
add to a stiff mud, then mix ithandful of soil, water make
well in your hand. Open your
hand and make a flat mud cake on
your palm (see Figure 33).
Slowly close your hand. The cake
should shine as your hand begins
to close. (If not, add water and
try again.) If the shine goes
away when your hand is opened
out flat again, it means that
the soil probably has a high proportioi, of sand or silt in
it. If the shine does not go
away, i. probably means that the Figure 33
soil contains a lot of clay.
Wet the soil until it becomes a stiff mud (thoroughly moist but
not watery). Roll the stiff mud into a pencil-thin worm of soil
about 10cm (4") long. The palm
of your hand can be used to roll
out the worm on a flat, hard
surface. Carefully pick up the
worm of stiff mud at one end
with just two of your fingers
(see Figure 34). Hold the worm
parallel to the ground. If the
worm breaks off, it contains a
lot of silt or sand. If it
bends or sags but does not break oft, it contains a lot of clay. Figure 34
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Preparing bricks for stove construction
If the stove is to be constructed with sun-dried or kiln-fired bricks, use clays that have very little sand. For sun-dried bricks, a mixture is made of 50 percent by volume of clay, 40 percent by volume of sawdust, and 10 percent by volume of a binder--ash or cow dung being preferred. These materials are mixed with water, placed in a mold, and left to dry in the sun. The bricks are joined together using mortar, live and sand, or clay and sand as mortar.
The inside of these stoves can be further protected from the hot corrosive gases by plastering with a mixture of water, clay (kaolin), and powdered quartz. If the latter is not available, cow dung mixed with a smali amount of clay can be used. Material from an ant hill, crushed fine and mixed with clay, also provides a heat-resistant coating.
If these clay bricks are fired in a kiln, they will last much longer. The bricks that are to be closest to the heat in the stove should be slop-molded. This involves mixing the clay with sawdust, 50 percent by volume. Water is added until the mixture is very wet. The mixture is then poured into a mold. When the brick is fired, it has a very open structure that can withstand high temperatures. This type of brick also provides insulation for the combustion chamber. However, these bricks are not very strong and must either be surrounded by sturdier bricks, or have an outer coating of lime or cement mortar.
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4. HOW TO BUILD FOUR STOVES
This chapter outlines general construction procedures for four
types of wood conserving cook stoves:
1. The Lorena stove 2. The smokeless chula 3. The Singer stove
4. A simple metal stove
stoves have been built and used successfuly. SomeAll of the
tomodification may be necessary to adapt the designs local
conditions. Complete construction references are found in the
Bibliography.
Lorena stove was developed in Guatemala. ItThe Lorena stove (see Figure 35)
resembles an improved Indian chula. It can reduce wood consump
tion by 25 to 50 percent if used properly.
An active program in Guatemala promotes the lorena design as
widely as possible. It has become very popular there and elsefor local familieswhere. Small businesses now build the stove
who do not want to build their own.
There are many reasons for this popularity. The stove can be
built by unskilled workers using local materials. Its size can arebe changed for different families. Only simple hand tools
needed. Most important, the basic technology can be adapted
broadly to different conditions and traditions.
The stove also offers these technical advantages:
55
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56
LORENA STOVE
CHI~
Figure 35
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57
1. The long tunnel system extracts heat from the flue gases. This he A-would otherwise be lost up the flue.
2. The high stove mass stores heat for cooking and baking even after the fire has died out.
3. The high mass of the firebox walls insulates the fire. This
results in higher temperatures and more complete combustion.
4. The damper system allows better control of the fire.
5. Pots fit deeply and tightly into the stove. They are insulated from outside air. No smoke escapes.
The stove is built from a mixture of sand and soil. This mixture is called lorena. The word comes from the Spanish words for mud (lodo) and sand (arena). The lorena is applied in layers to form a solid block. The chimney hole, pot holes, tunnels, and firebox are then excavated before the lorena hardens.
Construction takes from six hours to several days. It depends on the size of the stove, weather conditions, and the skill of the builder.
Materials
1. Clay or clay-soil. About 120 buckets are needed for one square meter.
2. Sand. About 120 buckets are needed for one square meter. 3. Water. 4. Sheetmetal. 5. Chimney pipe. 6. Material to make a base if one is desired. Some cultures
prefer to cook as closely as possible to the ground. Others prefer to cook while standing. If so, a base is needed. Concrete blocks, adobe, rammed earth, bricks, or large rocks can be used. The best choice depends on local materials and the individual stove design.
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58
Tools and equipment
1. Shovel 2. Spoon 3. Bucket 4. Machete or other large knife
Construction
DESIGN
The size and shape of the stove can be changed for different families or cultures. Local traditions are very important. So
are individual household patterns. Families use their cooking fires in different ways. Cooking pots may vary. Some cooks may
prefer to cook food quickly at high heat. Others may prefer to cook more slowly at lower heat.
Information must therefore be collected on cooking patterns, the type of pots to be used, and the size and type of firewood or other cooking fuels. The best people to provide this information are those who will actually use the stove. The stove will not be used effectively unless they participate.
Here are some things to keep in mind during the design process:
1. Pots that need the most heat should be placed over the firebox. Pots needing less heat can be placed further down the tunnel system.
2. One pothole may fit more than one pot.
3. Try to keep the hot gases under the pots for as long a time as possible. This can be done by bending the tunnel sharply as it passes beneath each pot (see Figure 36).
4. The cook should be able to reach the pots and damper easily.
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59
Figure M
5. The size of the firebox should fit the amount of fuel that is needed.
6. The dimensions of the different stove parts should follow the guidelines in Figure 37.
7. Lorena melts in the rain. Provide for rain cover if the stove is built outside.
8. Long rectangular stoves crack more easily than other shapes.
1. The Lorena Mix
The lorena stove is made from a mixture of sand and clay (or clay-soil). Sand forms the main mass of the stove. The clay holds it together. Water is used to help the process.
Almost any type of sand will work. Coarse sand is best. Sand that is very coarse or that has gravel in it should be sifted through a screen with a 5mm (1/4") mesh. Ocean sands should be washed to remove salt.
It is more difficult to get the right kind of clay. Pure clay is best. Clay-soil can also work well. Clay-soil must be excavated to avoid top soil and organic matter (see Figure 32, page 51). Local potters and adobe makers can help you find the best local clay.
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60
00t~
PIF
%%CD,',
lop. %I
IscI
Figures?
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61
Soils can also be judged by the way they feel. Clay feels
greasy. Sand feels gritty. Silt has a powdery feel. Try to
avoid silt. It offers neither structure nor bonding.
There is an easy way to test a clay sample. First wet the
sample until it becomes a stiff mud. It should be moist, but
not watery. Roll the sample so that it resembles a 10cm long
pencil or worm. Pick up this "worm" at one end witi two
fingers. Hold it parallel to the ground. It contains a lot of
clay if it bends or sags without breaking.
The next step is to test whether the clay can stand a firing.
Make a ball of damp clay. Place it in hot coals for an hour. Rub its surface with your thumb after it cools. It is no good
if it flakes.
The next step is to find the best ratio of soil to sand. Test
batches made with different ratios. The ratio for soil to sand
should be between 1:1 and 1:3. The ratic for pure clay to sand
should be between 1:3 and 1:5. Some clay soil will have a lot clay stoveof silt. The silt does not help the hold the
together. The clay may also have many lumps. If so, sift it
first through a 5mm screen. You can also grind it with your
feet.
It is best to mix the sand and clay when they are dry. Add
water only after the mixing is finished. The water does not
have to be clear. It can be murky. '' But it should not be salty.
An average stove with a top surface of one square meter
requires about 1/2 cubic meter of lorena mix. Approximately 200
litres of water will be needed for the mixture. This quantity
of water will probably fit into a 55-gallon drum.
There is a quick way to test whether the mix has the right
ratio of sand to clay. Take a handful of the mix. Add enough
water to make a patty in your hand. Press the patty slightly
against the hand. Turn your hand over, palm down, with your
fingers closed. Open your fingers slowly. The patty should fall
away cleanly. If it sticks to your hand or leaves a lot of mix
behind, there is too much clay. If it drops too quickly or
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62
falls apart, there is too much sand. Adjust the ratio of sand
and clay in the mix to adjust for the test results.
Another way to test the ratio in the mix is by -aking a series
of test blocks. First check whether each mix has the right
amount of water. Do this by making a hard packed ball in your
hand. It should measure about 5cm (2") in diameter. Throw the
ball lm (approximately 3') in the air. Let it fall and hit your
hand hard. Don't cushion it. The ball should stay intact. It is
too dry if it cracks. It is too wet if it comes apart. Be sure that all the mix samples have the right amount of water. Next
make the test blocks. Each block should be a rectangular form
approximately 30-1/2 X 13 X 10cm (1' X 5" X 4"). Pound the
blocks until each is good and hard. Use a rammed earth
technique, if available. Remove the frame. Let the blocks dry
completely. Test for strength, as shown in Figure 38. The
strongest block makes the best stove.
Figs're 38
Another test is to make a small stove, start a fire, and watch for cracks.
2. Make the Base
A base is needed if people cook their food while standing. It can be made from a variety of materials so long as it is solid
and does not shift. Concrete blocks, adobe, or bricks can be used to form a box. This is then filled with compacted earth. Other materials that have been used successfully include mor
tared rock, tree stumps, and even a heavy table. The base
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63
should be designed with toe space. This lets the cook work closer to and more easily with the stove (see Figure 39).
Foundatton
Figure 39
Mark the full size of the stove on the ground. Put the' first layer of adobe blocks 10cm (4") in f rom the mark on the sides where the cook will stand (see Figure 40). TIee foundation can be laid using any cement or lorena mixture to hold the blocks together.
I
000<
Fiur s
401 %%. 10
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64
The upper layers should overhang by a total of 10cm (4") on the cook's sides to allow foot space for comfort while cooking.
Build the foundation 40-45cm (16-20") high if the cook will be
standing up (see Figure 41).
4045
Figure41
FILL
~broken
foundation (see Figure 42) with soil, rocks,
adobe blocks, or
debris. Pack the material down and allow the foun
dation to dry overnight.
Figure 42
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65
3. Make the Stove Body
Mix and lay oae layer at a time onto the base (see Figure 43).
Use the tested mix. Pound the lorena in firmly with your ha